Battery module and method for manufacturing same

ABSTRACT

In a battery module in which battery cells are inserted and adhered to battery retention sections each having a hole and formed on a holder, an objective is to provide a technology for sufficiently filling the gap between the battery retention section of the holder and the battery cell with an adhesive. A deformable porous layer  40  is formed on an outer circumferential surface  11  of each battery cell  1 , and an adhesion layer  4  is formed by impregnating the porous layer  40  with an adhesive. Alternatively, the deformable porous layer  40  is formed on the outer circumferential surface  11  of each of the battery cells  1 , and an adhesive layer  46  including an adhesive is formed on the back side in an insertion direction with respect to the porous layer  40.

TECHNICAL FIELD

The present invention relates to a battery module including a batterycell and a holder for holding the battery cell, and a method formanufacturing the battery module.

BACKGROUND ART

A battery cell in a battery module is generally adhered to a holder. Forexample, a battery module disclosed in JP2013008655 (A) is formed byintegrally adhering multiple battery cells to a holder. This type ofbattery module is referred to as an assembled battery, and is applied invarious use applications such as, for example, batteries for vehicles.

In the battery module disclosed in JP2013008655 (A), battery retentionsections each having a hole are formed on the holder, and the batterycells are inserted in the battery retention sections. When manufacturingthis type of battery modules, an adhesive is injected into respectivegaps between inner circumferential surfaces of the battery retentionsections and outer circumferential surfaces of the battery cells in theholder, and adhesion parts are formed when the adhesive solidifies. Withthe method of injecting the adhesive between the inner circumferentialsurfaces of the battery retention sections and the outer circumferentialsurfaces of the battery cells (i.e., potting method), injection andsolidification of the adhesive takes a long time, resulting in inferiorworking efficiency.

In order to improve the working efficiency, for example, a conceivablemethod is to apply the adhesive on the outer circumferential surface ofthe battery cell, and insert, in the battery retention section of theholder, the battery cell having the adhesive applied thereon.

For the purpose of stably holding the battery cell in the holder, havingthe gap between the inner circumferential surface of the batteryretention section formed in the holder and the outer circumferentialsurface of the battery cell to be not too large is consideredpreferable.

In this case, the adhesive has to fill a narrow gap. However, since theadhesive has a relatively high viscosity, the frictional resistancebetween the inner circumferential surface of the battery retentionsection and the adhesive is relatively large, and uniformly applying andspreading the adhesive are difficult. Thus, uniformly spreading theadhesive throughout a narrow gap between the inner circumferentialsurface of the battery retention section and the outer circumferentialsurface of the battery cell has not been easy. When the adhesive is notspread throughout the gap between the inner circumferential surface ofthe battery retention section and the outer circumferential surface ofthe battery cell, and air is caught inside an adhesion layer, the sizeof an adhesion area between the solidified adhesive (i.e., adhesionpart) and a counterpart material (i.e., the inner circumferentialsurface of the battery retention section and/or the outercircumferential surface of the battery cell) may decrease or thestrength of the adhesion part itself may deteriorate. Thus, the strengthof adhesion between the adhesion part and the counterpart materialcannot be improved easily, and integrally adhering the battery cell andthe holder stably has been difficult.

SUMMARY OF INVENTION Technical Problem

The present invention has been made in view of the above describedcircumstances, and an objective is to provide a battery module in whicha gap between a battery retention section of a holder and a battery cellis filled sufficiently with an adhesion part, and a method formanufacturing the battery module.

Solution to Problem

A first method for manufacturing a battery module of the presentinvention solving the above described problem includes:

a preparing step of preparing a battery cell and a holder having abattery retention section with a hole; and an adhesion layer-formingstep of forming an adhesion layer on an outer circumferential surface ofthe battery cell; and an insertion step of inserting the battery cell inthe battery retention section of the holder, wherein,

in the adhesion layer-forming step, a deformable porous layer is formedon the outer circumferential surface of the battery cell and the porouslayer is impregnated with an adhesive to form an adhesion layerincluding the porous layer and the adhesive.

A second method for manufacturing a battery module of the presentinvention solving the above described problem includes:

a preparing step of preparing a battery cell and a holder having abattery retention section with a hole; an adhesion layer-forming step offorming an adhesion layer on an outer circumferential surface of thebattery cell; and an insertion step of inserting the battery cell in thebattery retention section of the holder, wherein

in the adhesion layer-forming step,

a deformable porous layer is formed in a first area which is a part ofthe outer circumferential surface of the battery cell, and

an adhesive layer including an adhesive is formed on a second arealocated adjacent to the first area and on a back side thereof in aninsertion direction for the battery cell to form an adhesion layerincluding the porous layer and the adhesive.

A battery module of the present invention solving the above describedproblem includes:

a holder having a battery retention section with a hole; a battery cellinserted in the battery retention section of the holder; and an adhesionpart interposed between the holder and the battery cell, wherein

the adhesion part includes a porous layer, and an adhesive at leastpartially impregnating the porous layer.

Advantageous Effects of Invention

With the first or second method for manufacturing the battery module ofthe present invention, the adhesive can sufficiently fill the gapbetween the battery retention section of the holder and the batterycell. The battery module of the present invention has the gap betweenthe battery retention section of the holder and the battery cell filledsufficiently with the adhesive.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a perspective view schematically showing a battery module ofExample 1;

FIG. 2 is an exploded perspective view schematically showing the batterymodule of Example 1;

FIG. 3 is a cross sectional view schematically showing the batterymodule of Example 1 cut at X-X position in FIG. 1;

FIG. 4 is an illustrative diagram schematically showing an adhesionlayer-forming step of the manufacturing method of Example 1;

FIG. 5 is an illustrative diagram schematically showing an insertionstep of the manufacturing method of Example 1;

FIG. 6 is an illustrative diagram schematically showing an adhesionlayer-forming step of a manufacturing method of Example 2;

FIG. 7 is an illustrative diagram schematically showing an insertionstep of the manufacturing method of Example 2;

FIG. 8 is an illustrative diagram schematically showing an adhesionlayer-forming step of a manufacturing method of Example 3; and

FIG. 9 is an illustrative diagram schematically showing an insertionstep of the manufacturing method of Example 3.

DESCRIPTION OF EMBODIMENTS

In the following, a method for manufacturing a battery module of thepresent invention is described with specific examples. In the following,if necessary, a method for manufacturing a battery module in eachExample is abbreviated simply as a manufacturing method of each of theExamples.

Unless mentioned otherwise in particular, a numeric value range of “x toy” described in the present specification includes, in a range thereof,a lower limit “x” and an upper limit “y.” A numeric value range can beformed by arbitrarily combining such upper limit values, lower limitvalues, and numerical values described in embodiments. In addition,numerical values arbitrarily selected within the numeric value range canbe used as upper limit and lower limit numerical values.

Example 1

Example 1 relates to the first method for manufacturing the batterymodule of the present invention. FIG. 1 is a perspective viewschematically showing a battery module of Example 1. FIG. 2 is anexploded perspective view of the battery module of Example 1 shown inFIG. 1. FIG. 3 is a cross sectional view schematically showing thebattery module of the Example 1 cut at X-X position in FIG. 1. FIG. 4 isan illustrative diagram schematically showing an adhesion layer-formingstep of the manufacturing method of Example 1. FIG. 5 is an illustrativediagram schematically showing an insertion step of the manufacturingmethod of Example 1.

In the following Examples, up, down, left, right, front, and backrespectively refer to up, down, left, right, front, and back shown inFIG. 1. In each of the Examples, an axial direction Y of a battery cellrefers to up-down direction shown in FIG. 1. The axial direction Y of amember other than a battery cell refers to a direction that matches theaxial direction Y in an assembled state shown in FIG. 1. In addition, inthe following, an insertion direction for a battery cell refers to adirection that matches the axial direction Y.

<Battery Module Manufacturing Method>

The method for manufacturing the battery module of Example 1 is a methodfor manufacturing a battery module having battery cells 1, adhesionparts 42, and a holder 5 (cf., FIGS. 1 and 2).

Each of the battery cells 1 is inserted in a penetration hole of abattery retention section 50 of the holder 5. As described later, eachof the adhesion parts 42 is a layer including a porous layer 40 and asolidified adhesive, and is interposed between an inner circumferentialsurface 51 of a battery retention section 50 and an outercircumferential surface 11 of each of the battery cells 1 to bind thetwo. The method for manufacturing the battery module of Example 1includes a preparing step, an adhesion layer-forming step, and aninsertion step.

(Preparing Step)

In the preparing step, the battery cells 1 and the holder 5 areprepared. The battery cells 1 are substantially columnar, and each ofthe battery retention sections 50 of the holder 5 has a penetration holewith a slightly larger diameter than the outer diameter of each of thebattery cells 1. In an assembled state as shown in FIGS. 1 and 3, eachof the battery cells 1 has a portion disposed inside the batteryretention section 50 in the holder 5, and other portions, i.e., portionsdisposed outside the battery retention section 50. Thus, in theassembled state, each of the outer circumferential surfaces 11 of thebattery cells 1 has an area (referred to as binding area Z) facing theinner circumferential surface 51 of the battery retention section 50 ofthe holder 5, and other areas. A binding area Z is formed of an areathat is a part of the outer circumferential surface 11 of each of thebattery cells 1 in the axial direction Y. The binding area Z iscontinuously formed on the whole circumference in the circumferentialdirection of each of the battery cells 1. A gap between the innercircumferential surface 51 of the battery retention section 50 and theouter circumferential surface 11 of each of the battery cells 1 isreferred to as an adhesion space 20.

(Adhesion Layer-Forming Step)

As shown in FIG. 4, in the adhesion layer-forming step in themanufacturing method of Example 1, first, the porous layer 40, which iscylindrical, is disposed on the outer circumferential surface 11 of eachof the battery cells 1. In Example 1, the porous layer 40 is formed bywinding, around the outer circumferential surface 11 of each of thebattery cells 1, a sponge tape obtained by laminating an adhesive layer(not shown) for tapes on the back surface of a tape made from sponge.The tape of the porous layer 40, i.e., the sponge portion, is made of anopen-cell type foamed urethane resin and is elastically deformable.

Next, the porous layer 40 is impregnated with a fluid adhesive. Themethod for impregnating the porous layer 40 with the adhesive is notparticularly limited, and a known method may be appropriately selecteddepending on the type of the adhesive, and the diameter of the finepores of the porous layer 40, etc. For example, when the adhesive haslow viscosity, i.e., when fluidity of the adhesive is relatively high,or when the diameter of the fine pores of the porous layer 40 is large,the porous layer 40 can be impregnated with the adhesive by simplyapplying the adhesive on the porous layer 40. In addition, for example,when the adhesive has a relatively high viscosity, i.e., when fluidityof the adhesive is relatively low, or when the diameter of the finepores of the porous layer 40 is relatively small, the porous layer 40can be impregnated with the adhesive by disposing the porous layer 40 oneach of the battery cells 1, applying the adhesive on the surface of theporous layer 40, and placing each of the battery cells 1 in a reducedpressure atmosphere such as in a vacuum chamber. The method forimpregnating the porous layer 40 with the adhesive is not limited tothose described above, and various methods may be used. By impregnatingthe porous layer 40 with the adhesive, an adhesion layer 4 formed of theporous layer 40 and the adhesive can be formed on the outercircumferential surface 11 of each of the battery cells 1.

With this step, the adhesion layer 4 obtained by impregnating the porouslayer 40 with the adhesive is formed. Each of the adhesion parts 42 ofthe battery module of Example 1 is formed when the adhesion layer 4 isleft still and solidified.

The outer diameter of the adhesion layer 4 before insertion is largerthan the hole diameter of the battery retention section 50 of the holder5. Thus, the thickness of the adhesion layer 4 at this moment is largerthan the distance between the outer circumferential surface 11 of eachof the battery cells 1 and the inner circumferential surface 51 of thebattery retention section 50 in the assembled state. In other words, asshown in the left side portion of FIG. 5, at the time when respectiveaxes of the battery retention section 50 of the holder 5 and one of thebattery cells 1 are aligned before the insertion step (hereinafter, ifnecessary, referred to “upon axis alignment”); an outer circumferentialsurface 41 of the cylindrical adhesion layer 4 is positioned outward inthe radial direction from the inner circumferential surface 51 of thebattery retention section 50. The internal diameter of the substantiallycylindrical adhesion layer 4 is smaller than the hole diameter of thebattery retention section 50. Thus, in order to fit the innercircumferential surface of the cylindrical adhesion layer 4 to the outercircumferential surface 11 of each of the battery cells 1, upon axisalignment, the inner circumferential surface of the adhesion layer 4 ispositioned inward in the radial direction from the inner circumferentialsurface 51 of the battery retention section 50.

In the manufacturing method of Example 1, the thickness of the porouslayer 40 is about 1.0 to 2.0 mm, and the thickness of the adhesion layer4 is about 0.4 to 1.0 mm. In addition, the width of the adhesion space20 is about 0.1 to 0.4 mm. The difference between the thickness of theadhesion layer 4 and the width of the adhesion space 20 is about 0 to0.4 mm. Here, the thickness of the porous layer 40 and the thickness ofthe adhesion layer 4 both refer to an average of thicknesses of each ofthe layers, and the width of the adhesion space 20 refers to an averageof the distance between the outer circumferential surface 11 of each ofthe battery cells 1 and the inner circumferential surface 51 of thebattery retention section 50.

(Insertion Step)

After the adhesion layer-forming step described above, each of thebattery cells 1 having the adhesion layer 4 formed thereon is alignedwith the battery retention section 50 of the holder 5 using respectiveaxes, and each of the battery cells 1 is inserted in the batteryretention section 50. Specifically, as shown in the left side portion inFIG. 5, the battery cells 1 are moved along the axial direction Y withrespect to the holder 5 that is fixed, and, as shown in the centralportion in FIG. 5, the battery cells 1 are inserted in the respectivebattery retention sections 50. At this moment, the battery cells 1 havemoved relative to the holder 5 upward from below in FIG. 1.

As described above, the adhesion layer 4 is disposed on the outercircumferential surface 11 of each of the battery cells 1. In addition,the thickness of the adhesion layer 4 is larger than the width of theadhesion space 20. Thus, as shown in the central portion in FIG. 5, wheninserting each of the battery cells 1 in the battery retention section50, the adhesion layer 4 is pressed against an insertion edge 52 of thebattery retention section 50 and the inner circumferential surface 51,and penetrates the adhesion space 20 while being compressed.

As described above, the adhesion layer 4 includes the porous layer 40having a large number of fine pores, and the porous layer 40 isdeformable. Thus, in the insertion step, the porous layer 40 in theadhesion layer 4 is deformed and is pressed toward the adhesion space20. Since the porous layer 40 can retain its own shape by itself, theporous layer 40 penetrates the adhesion space 20 as a whole while beingaccompanied by a certain degree of compressive deformation as shown inthe central portion in FIG. 5.

At this moment, associated with the deformation of the porous layer 40,one portion of the adhesive impregnating the fine pores of the porouslayer 40 leaks outside the porous layer 40, and moves to the surface ofthe porous layer 40, i.e., the surface of the adhesion layer 4. Sincethe adhesive is a fluid and can deform more easily than the porous layer40 and the battery retention section 50, the adhesive functions as alubricant for the porous layer 40. On the other hand, since the porouslayer 40 is able to retain shape, the porous layer 40 functions as apressing material for applying and spreading the adhesive. Thus, in theinsertion step, as the porous layer 40 penetrates the adhesion space 20,the adhesive held in the porous layer 40 also penetrates the adhesionspace 20, the adhesive is applied and spread within the adhesion space20 along the inner circumferential surface 51 of the battery retentionsection 50, and the porous layer 40 further advances forward in theinsertion direction due to lubricative action of the adhesive. In thismanner, the adhesion layer 4 fills the adhesion space 20 without leavingany gaps.

(Cell Binding Step)

After the insertion step described above, a complex, formed of thebattery cells 1, the holder 5, and the adhesion layers 4 and obtainedwhen the battery cells 1 are inserted in the battery retention section50 and the adhesion space 20 is filled with the adhesion layer 4, isleft still to enable the liquid adhesive to harden into a solid state toobtain the battery module of Example 1 including the adhesion parts 42,the battery cells 1, and the holder 5.

The length of the porous layer 40 in the axial direction after theinsertion step is substantially identical to the length of the bindingarea Z in the axial direction, and the length of the adhesion parts 42in the battery module in the axial direction is also substantiallyidentical to the length of the binding area Z in the axial direction.

With the manufacturing method of Example 1, as a result of the adhesionlayer 4 being formed of two elements, i.e., the porous layer 40 and theadhesive, and causing the porous layer 40 and the adhesive to affecteach other in the insertion step; the battery module in which theadhesion layer 4 sufficiently fills the gap between the batteryretention section 50 of the holder 5 and each of the battery cells 1 canbe manufactured easily.

In other words, in the battery module obtained from the manufacturingmethod of Example 1, the adhesion layer 4 including the porous layer 40and the adhesive fills the gap between the battery retention section 50of the holder 5 and each of the battery cells 1, and an excellentadhesive strength is obtained for each of the adhesion parts 42 formedthrough solidification of the adhesion layer 4.

The manufacturing method of the present invention is achieved as longas, as described above, the porous layer 40 is deformable, and theadhesive has a fluidity higher than the porous layer 40 and is moreeasily deformed than the porous layer 40. In other words, the porouslayer 40 is a deformable solid and the adhesive is a fluid. Furthermore,the solid porous layer 40 does not break even when being deformed, andthe fluid adhesive has fluidity and conforms to the shape of acounterpart. With the manufacturing method of the present invention, asa result of combining the adhesive and the porous layer 40 as describedabove; the battery module in which the adhesion layer 4 sufficientlyfills the gap between the battery retention section 50 of the holder 5and each of the battery cells 1 can be manufactured easily.

In the adhesion layer-forming step of the manufacturing method ofExample 1, although the porous layer 40 is disposed over the wholecircumference of the outer circumferential surface 11 of each of thebattery cells 1; in the adhesion layer-forming step of the manufacturingmethod of the present invention, the porous layer 40 does not have to bedisposed over the whole circumference of the outer circumferentialsurface 11 of each of the battery cells 1. For example, the porous layer40 may be provided with one or more slits extending in the axialdirection Y. In this case, when the amount of deformation of the porouslayer 40 is sufficiently large and the width of the slit is sufficientlysmall, the slit closes at the insertion step when the porous layer 40deforms. Since the adhesive follows the porous layer 40 and fills theslit, the adhesion layer 4 is formed practically on the wholecircumference of the outer circumferential surface 11 of each of thebattery cells 1.

In the adhesion layer-forming step, although the adhesive preferablyimpregnates the whole porous layer 40, a portion not impregnated withthe adhesive may partially exist in the porous layer 40 at the adhesionlayer-forming step. By having the adhesive move associated withdeformation of the porous layer 40 at the insertion step, the part ofthe porous layer 40 not impregnated with the adhesive at the adhesionlayer-forming step may also be provided with the adhesive at theinsertion step depending on the amount of deformation of the porouslayer 40. Considering the adhesive property of the adhesion layer 4, theadhesion layer 4 preferably contains a large amount of the adhesive, andthe adhesive preferably impregnates the porous layer 40 at a level wherethe surface of the porous layer 40 is soaked at the adhesionlayer-forming step.

Although the porous layer 40 is elastically deformable in themanufacturing method of Example 1; the manufacturing method of thepresent invention is achieved as long as the porous layer 40 isdeformable and may deform plastically. When the porous layer 40 iselastically deformable, the porous layer 40, which has elasticallydeformed due to being pressed against the inner circumferential surface51 of the battery retention section 50 and/or the insertion edge 52 ofthe holder 5 at the insertion step, fills the adhesion space 20 becauseof its own elasticity. The adhesive that has leaked from the porouslayer 40 at the time of deformation is absorbed again by the porouslayer 40 when the porous layer 40 returns to its original shape throughelasticity. In this case, the adhesion space 20 is filled with theporous layer 40 holding the adhesive sufficiently, i.e., the adhesionlayer 4. In addition, by having the adhesive absorbed by the porouslayer 40 again, leakage of the adhesive from the battery cells 1 at anend in the axial direction Y can be suppressed. As a result, loss of theadhesive can be suppressed, and formation of an insulation part by anyleaked adhesive near an end of any one of the battery cells 1, i.e.,near a terminal section of one of the battery cells 1, in the axialdirection Y can be suppressed.

Although the porous layer 40 may be electrically conductive as long asthe porous layer 40 does not touch the terminal section, obviously, theporous layer 40 is preferably electrically insulative. Examples ofmaterials for the electrically insulative porous layer 40 includeresins, rubbers, elastomers, and glass fibers, etc. These materials maybe formed into a three dimensional shape of, for example, a sponge, anonwoven fabric, a woven fabric, a net, a coil, and/or a brush to beused as the porous layer 40. The number, shape, and degree of porosityof the fine pores in the porous layer 40 are not particularly limited.However, the porous layer 40 is preferably an open-cell type,considering the porous layer 40 is to be impregnated with the adhesive.An open-cell type porous layer 40 refers to a porous layer 40 whose finepores are interconnected cells, and, more specifically, refers to aporous layer 40 in which at least one portion of fine pores arecommunicatively connected with each other to form penetration holes. Onthe other hand, a closed-cell type porous layer 40 refers to a porouslayer 40 whose fine pores are isolated cells, and, more specifically,refers to a porous layer 40 in which fine pores are independent fromeach other and are not communicatively connected.

The porous layer 40 used in the first method for manufacturing thebattery module has to be an open-cell type. The porous layer 40 used inthe second method for manufacturing the battery module may be anopen-cell type or a closed-cell type, but an open-cell type ispreferable. Considering the impregnation with the adhesive, the averagepore size of the fine pores in the porous layer 40 is preferably notsmaller than 100 μm and more preferably not smaller than 1000 μm. Theaverage pore size can be measured with a nitrogen gas adsorption method.

Although any adhesive may be used, and the material, viscosity, and thelike thereof are not particularly limited; an angle of contact withrespect to the porous layer 40 before solidification is preferablysmall. Specifically the angle of contact is preferably not larger than30° and more preferably not larger than 15°.

In the following, the battery module of Example 1 will be described asreference.

<Battery Module>

A battery module of Example 1 is obtained through the method formanufacturing a battery module of Example 1. As shown in FIGS. 1 and 2,the battery module of Example 1 includes the battery cells 1, theadhesion parts 42, the holder 5, a separator 90, and bus bars 91.

The battery module of Example 1 holds sixteen of the battery cells 1.The battery cells 1 are cylindrical cells having substantially the sameshape, and each have terminals 19 (positive electrode terminal andnegative electrode terminal) on both ends in the axial direction Y. Theholder 5 has a substantially plate-like shape, and holds sixteen of thebattery retention sections 50. Each of the battery retention sections 50is formed with a penetration hole, and the internal diameter of each ofthe battery retention sections 50 is slightly larger than the outerdiameter of each of the battery cells 1. The battery cells 1 areinserted in the respective battery retention sections 50. In the batterymodule of Example 1, four of the battery cells 1 are connected in seriesby one of the bus bars 91 as one set. A conductive material layer, whichis not shown in the figures, is disposed between the bus bars 91 and thebattery cells 1. The conductive material layer is a layer forelectrically connecting the bus bars 91 and the terminals 19 of thebattery cells 1. The shape of the conductive material layer is notparticularly limited, and may be formed using a known method such as tabwelding, wire bonding, and brazing, etc.

The separator 90 is locally interposed between the bus bars 91 and thebattery cells 1. The separator 90 is a member for connecting the batterycells 1 through the bus bars 91 while preventing short circuiting bypartially blocking electric connection between the battery cells 1 andthe bus bars 91. The separator 90 may be formed of an insulatingmaterial, and is made of an insulation resin in the present example.

Each of the adhesion parts 42 is a layer that is formed of the hardenedadhesive and the porous layer 40, interposed between the innercircumferential surface 51 of the battery retention section 50 formed onthe holder 5 and the outer circumferential surface 11 of each of thebattery cells 1, and bound to the inner circumferential surface 51 ofthe battery retention section 50 and the outer circumferential surface11 of each of the battery cells 1. As shown in FIG. 3, each of theadhesion parts 42 has a two-phase structure formed of the porous layer40 and the adhesive impregnating the porous layer 40. In other words, ineach of the adhesion parts 42, the adhesive is dispersed in a matrixformed by the porous layer 40. Each of the adhesion part 42 is disposedthroughout the whole binding area Z of each of the battery cells 1. Inthe binding area Z, each of the adhesion parts 42 is interposed betweenthe outer circumferential surface 11 of each of the battery cells 1 andthe inner circumferential surface 51 of the battery retention section 50over the whole circumference of each of the battery cells 1. Thus, eachof the adhesion parts 42 in Example 1 has a substantially cylindricalshape as shown in FIG. 2. The inner circumferential surface of each ofthe adhesion parts 42 is in contact with the outer circumferentialsurface 11 of each of the battery cells 1, and the outer circumferentialsurface 41 of each of the adhesion parts 42 is in contact with the innercircumferential surface 51 of the battery retention section 50. Thus, inthe binding area Z, each of the adhesion parts 42 is spread throughoutthe gap between the outer circumferential surface 11 of each of thebattery cells 1 and the inner circumferential surface 51 of the batteryretention section 50, and is loaded over the whole circumference in thecircumferential direction and the full length in the axial directionwithout leaving any gaps.

With the manufacturing method of Example 1, as described above,substantially the whole adhesion layer 4 penetrates the adhesion space20 at the insertion step. As shown in FIG. 3, in the battery module ofExample 1 obtained from the manufacturing method of Example 1, theamount each of the adhesion parts 42 that leaks out or remains at theback edge of the battery retention section 50 in the insertion directionis very small. The reason is because, at the insertion step, the porouslayer 40 capable of retaining its shape is located forward in theinsertion direction, and the porous layer 40 draws the adhesive into theadhesion space 20. In addition, since the porous layer 40 holds theadhesive in the fine pores, the amount of the adhesion parts 42 leakingout on the front edge in the insertion direction of the battery cells 1is also very small. Thus, in the battery module of Example 1,contamination of the battery cells 1 and the battery retention section50 by an adhesive is suppressed.

Example 2

Example 2 relates to the second method for manufacturing the batterymodule of the present invention. A manufacturing method of Example 2 isroughly identical to the manufacturing method of Example 1 except forthe adhesion layer-forming step. A battery module of Example 2 isroughly identical to the battery module of Example 1 except for theadhesion layer. As a result, the preparing step and the cell bindingstep in the manufacturing method of Example 2 are roughly identical tothose in the manufacturing method of Example 1. Thus, only the adhesionlayer-forming step and the insertion step are described in Example 2.FIG. 6 is an illustrative diagram schematically showing the adhesionlayer-forming step of the manufacturing method of Example 2. FIG. 7 isan illustrative diagram schematically showing the insertion step of themanufacturing method of Example 2.

(Adhesion Layer-Forming Step)

At the adhesion layer-forming step of the manufacturing method ofExample 2, a porous layer 40 whose length in the axial direction issmaller than that of Example 1 is formed on the outer circumferentialsurface 11 of each of the battery cells 1, and this porous layer 40 isimpregnated with the same adhesive as in Example 1. An area where theporous layer 40 is formed on the outer circumferential surface 11 ofeach of the battery cells 1 is referred to as a first area I. The firstarea I is an area located forward in the insertion direction on theouter circumferential surface 11 of each of the battery cells 1.

At a second area II located adjacent to the first area I and on the backside thereof in the insertion direction on the outer circumferentialsurface 11 of each of the battery cells 1, an adhesive having a higherviscosity than the adhesive impregnating the porous layer 40 is appliedto form the adhesive layer. “The adhesive having a high viscosity” canalso be rephrased as “an adhesive capable of maintaining a relativeposition between a battery cell and holder to enable easy retention ofshape also in the insertion step,” or “an adhesive having low fluiditycompared to a low viscosity adhesive.” In addition, “low viscosityadhesive” can also be rephrased as “an adhesive capable of functioningas a lubricant at the insertion step,” or “an adhesive having highfluidity compared to a high viscosity adhesive.” In the following, ifnecessary, the adhesive forming the adhesive layer is referred to as ahigh viscosity adhesive, and the adhesive impregnating the porous layer40 is referred to as a low viscosity adhesive. A layer including theporous layer 40 and the adhesive impregnating the porous layer 40 isreferred to as a front part 45, and a layer including a high viscosityadhesive is referred to as a back part 46. Thus, in the manufacturingmethod of Example 2, the adhesion layer 4 is formed from the front part45 and the back part 46. The back part 46 in the manufacturing method ofExample 2 corresponds to the adhesive layer in the manufacturing methodof the present invention.

The front part 45 is, except for its length in the axial direction,roughly identical to the adhesion layer 4 in the manufacturing method ofExample 1. The thickness of the front part 45 and the thickness of theback part 46 are substantially identical, and these thicknesses aresubstantially identical to the thickness of the adhesion layer 4 inExample 1. An insertion-direction front edge 47 of the back part 46 isin contact with an insertion-direction back edge 48 of the front part45. The front part 45 and the back part 46 are both disposed over thewhole circumference of the outer circumferential surface 11 of each ofthe battery cells 1.

As shown in the left side portion of FIG. 7, upon axis alignment, theouter circumferential surface of the front part 45 and the outercircumferential surface of the back part 46 having a cylindrical shapeare positioned outward in the radial direction from the innercircumferential surface 51 of the battery retention section 50. Also inthe manufacturing method of Example 2, the thickness of the porous layer40 is about 1.0 to 2.0 mm, and the thickness of the adhesion layer 4 isabout 0.4 to 1.0 mm. In addition, the width of the adhesion space 20 isabout 0.1 to 0.4 mm. The difference between the thickness of theadhesion layer 4 and the width of the adhesion space 20 is about 0 to0.4 mm.

(Insertion Step)

After the adhesion layer-forming step described above, each of thebattery cells 1 having the adhesion layer 4 formed thereon is alignedwith the battery retention section 50 of the holder 5 using respectiveaxes, and each of the battery cells 1 is inserted in the batteryretention section 50. The thickness of the adhesion layer 4 disposed onthe outer circumferential surface 11 of each of the battery cells 1 islarger than the width of the adhesion space 20. Thus, also in themanufacturing method of Example 2, when inserting the battery cells 1 inthe battery retention section 50, the adhesion layer 4 is pressedagainst the insertion edge 52 of the battery retention section 50 andthe inner circumferential surface 51 of the battery retention section50. The front part 45 that forms the forward portion of the adhesionlayer 4 in the insertion direction includes, similarly to the adhesionlayer 4 of Example 1, the deformable porous layer 40, and an adhesivehaving a higher fluidity than the porous layer 40 and capable ofdeforming easier than the porous layer 40. Thus, the front part 45penetrates, similarly to the adhesion layer 4 of Example 1, the adhesionspace 20 without leaving any gaps through interaction between the porouslayer 40 and the adhesive. On the other hand, although the back part 46located adjacent to the front part 45 does not include the porous layer40, the back part 46 is drawn by the front part 45 and penetrates theadhesion space 20. Since the adhesive included in the back part 46 is ahigh viscosity adhesive whose viscosity is higher than that of the lowviscosity adhesive included in the front part 45, similarly to theporous layer 40 of the front part 45, the back part 46 slides into theadhesion space 20 through lubricative action of the low viscosityadhesive, and applies and spreads the low viscosity adhesive over theinner circumferential surface 51 of the battery retention section 50. Asa result, similarly to the front part 45, the back part 46 also fillsthe adhesion space 20 without leaving any gaps. Thus, at the insertionstep, the adhesion layer 4 fills the adhesion space 20 without leavingany gaps over the whole circumference in the circumferential directionand the full length in the axial direction.

Thus, also with the manufacturing method of Example 2, the batterymodule in which the adhesion layer 4 sufficiently fills the gap betweenthe battery retention section 50 of the holder 5 and each of the batterycells 1 can be manufactured easily.

In the adhesion layer-forming step of the manufacturing method ofExample 2, although the length of the front part 45 in the axialdirection and the length of the back part 46 in the axial direction aresubstantially the same, the ratio of the length of the front part 45 inthe axial direction with respect to the length of the back part 46 inthe axial direction is not particularly limited, as long as the shape ofthe front part 45 can be sufficiently retained.

With regard to the high viscosity adhesive used for the back part 46, aslong as the viscosity is higher than that of the low viscosity adhesiveat the insertion step, the viscosities before the adhesion layer-formingstep and after the insertion step are not particularly limited.

In Example 2, although the back part 46 includes the high viscosityadhesive and the front part 45 includes the low viscosity adhesive; theadhesive included in the back part 46 and the adhesive included in thefront part 45 may be the same. In addition, the adhesive included in thefront part 45 may be the high viscosity adhesive and the adhesiveincluded in the back part 46 may be the low viscosity adhesive. In allcases, since the front part 45 penetrates the adhesion space 20 based oninteraction between the porous layer 40 and the adhesive, and the backpart 46 in contact with the front part 45 is also drawn into theadhesion space 20 by the front part 45; the adhesion space 20 is filledwith the adhesion layer 4 without leaving any gaps over the wholecircumference in the circumferential direction and the full length inthe axial direction.

Although the front part 45 and the back part 46 are preferably disposedso as to make contact with each other at the adhesion layer-formingstep, for example, the front part 45 and the back part 46 may beslightly spaced at the adhesion layer-forming step. In this case, whenthe front part 45 that has deformed at the insertion step and hasswelled at the back in the insertion direction makes contact with theback part 46, the back part 46 is drawn by the front part 45 andpenetrates the adhesion space 20 similarly.

An adhesive in the present invention refers to a composition that canchange from a fluid into a solid, and can bind, when changing from afluid into a solid, at least the outer circumferential surface 11 ofeach of the battery cells 1 and the inner circumferential surface 51 ofthe battery retention section 50. For example, the adhesive may be afluid at the insertion step, i.e., when each of the battery cells 1 isbeing inserted in the battery retention section 50. Any adhesive may beused as long as, at the cell binding step, i.e., after each of thebattery cells 1 is inserted in the battery retention section 50, theadhesive can harden because of a chemical reaction, evaporation of asolvent, or the like, change into a solid from a fluid, and bind theinner circumferential surface 51 of the battery retention section 50 andthe outer circumferential surface 11 of each of the battery cells 1.Here, a fluid refers to a state of capable of flowing, and is a conceptincluding forms such as liquid, gel, sol, and slurry. Specific examplesof the adhesive include reactive-type adhesives, solvent basedadhesives, emulsion adhesives, hot-melt adhesives, and synthetic rubberbased adhesives, etc.

Any high viscosity adhesive can be used as long as the high viscosityadhesive has a higher viscosity than that of the low viscosity adhesive,and the high viscosity adhesive and the low viscosity adhesive may beformed from different materials, or may be formed from the samematerial. The viscosity of the adhesive can be adjusted using variousmethods. For example, the viscosity can be adjusted by appropriatelysetting molecular weights of resin components such as oligomers andpolymers included in the adhesive. Generally, a resin component with alow molecular weight is regarded to have low viscosity when compared toa resin component with a high molecular weight. Alternatively theviscosity of the adhesive can be adjusted by blending various fillers tothe adhesive. Furthermore, the viscosity of the adhesive can also beadjusted by appropriately setting the type and amount of the filler.When a filler with small particle size is used, depending on the typeand particle size of the filler, etc., the viscosity of the adhesive isgenerally said to increase as the blended amount of the fillerincreases. When the adhesive is a solvent based adhesive or an emulsionadhesive, the viscosity of the adhesive can be adjusted by appropriatelyadjusting the blending ratio of the solvent or dispersion medium (i.e.,solid content concentration of the adhesive). The viscosity of theadhesive increases when the solid content concentration is higher.Furthermore, the viscosity of the adhesive can also be adjusted byappropriately changing the mixing ratio of a main agent and a curingagent, and the type of the main agent and/or the curing agent.

The battery module of Example 2 obtained by the manufacturing method ofExample 2 is roughly identical to the battery module of Example 1 exceptfor the adhesion parts 42, and is largely different from the batterymodule of Example 1 regarding that the porous layer 40 exists only atthe front part 45 and the porous layer 40 does not exist at the backpart 46.

Example 3

Example 3 relates to the second method for manufacturing the batterymodule of the present invention. A manufacturing method of Example 3 isalso roughly identical to the manufacturing method of Example 1 exceptfor the adhesion layer-forming step. A battery module of Example 3 isroughly identical to the battery module of Example 1 except for theadhesion part. Thus, similarly to Example 2, only the adhesionlayer-forming step and the insertion step are described in Example 3.FIG. 8 is an illustrative diagram schematically showing the adhesionlayer-forming step of the manufacturing method of Example 3. FIG. 9 isan illustrative diagram schematically showing the insertion step of themanufacturing method of Example 3.

(Adhesion Layer-Forming Step)

As shown in FIG. 8, at the adhesion layer-forming step of themanufacturing method of Example 3, a porous layer 40 whose length in theaxial direction is shorter than that of Example 2 is formed at the firstarea I on the outer circumferential surface 11 of each of the batterycells 1, and the porous layer 40 is not impregnated with the adhesive.The high viscosity adhesive identical to that in Example 2 is applied onthe second area II to form an adhesive layer. Thus, in Example 3, thefront part 45 does not include the adhesive, the length L1 of the frontpart 45 in the axial direction is shorter than that in Example 2, andthe length L2 of the back part 46 in the axial direction is longer thanthat in Example 2. A sum of the length L1 of the front part 45 in theaxial direction and the length L2 of the back part 46 in the axialdirection, i.e., the length of the adhesion layer 4 in the axialdirection, is identical to that in Example 2. In addition, the thicknessof the adhesion layer 4 is also identical to that in Example 2. Theinsertion-direction front edge 47 of the back part 46 is in contact withthe insertion-direction back edge 48 of the front part 45. The frontpart 45 and the back part 46 are both disposed over the wholecircumference of the outer circumferential surface 11 of each of thebattery cells 1.

As shown in the left side portion of FIG. 9, upon axis alignment, theouter circumferential surface of the front part 45 and the outercircumferential surface of the back part 46 having a cylindrical shapeare positioned outward in the radial direction from the innercircumferential surface 51 of the battery retention section 50. Also inthe manufacturing method of Example 3, the thickness of the porous layer40 is about 1.0 to 2.0 mm, and the thickness of the adhesion layer 4 isabout 0.4 to 1.0 mm. In addition, the width of the adhesion space 20 isabout 0.1 to 0.4 mm. The difference between the thickness of theadhesion layer 4 and the width of the adhesion space 20 is about 0 to0.4 mm.

(Insertion Step)

After the adhesion layer-forming step described above, each of thebattery cells 1 having the adhesion layer 4 formed thereon is alignedwith the battery retention section 50 of the holder 5 using respectiveaxes, and each of the battery cells 1 is inserted in the batteryretention section 50. The thickness of the adhesion layer 4 disposed onthe outer circumferential surface 11 of each of the battery cells 1 islarger than the width of the adhesion space 20. Thus, as shown in thecentral portion in FIG. 9, also in the manufacturing method of Example3, when inserting the battery cells 1 in the battery retention section50, the adhesion layer 4 is pressed against the insertion edge 52 of thebattery retention section 50 and the inner circumferential surface 51 ofthe battery retention section 50.

The front part 45 of the adhesion layer 4 consists only of thedeformable porous layer 40. Thus, although the front part 45 does nothave any lubricative action by an adhesive, the porous layer 40penetrates the adhesion space 20 without leaving any gaps by its ownshape retention force. On the other hand, although the back part 46located adjacent to the front part 45 does not include the porous layer40; similarly to Example 2, the back part 46 is drawn by the front part45 and penetrates the adhesion space 20. Since the back part 46 includesthe adhesive, the back part 46 slides in the adhesion space 20 throughits own lubricative action and the adhesive is applied and spread overthe inner circumferential surface 51 of the battery retention section50. The insertion-direction front edge 47 of the back part 46 being incontact with the front part 45 can be rephrased as the back part 46being adhered to the front part 45. Thus, the back part 46 is drawn bythe front part 45 as a whole and fills the adhesion space 20 withoutleaving any gaps. As a result, also in the manufacturing method ofExample 3, at the insertion step, the adhesion space 20 is filled withthe adhesion layer 4 without leaving any gaps over the wholecircumference in the circumferential direction and the full length inthe axial direction.

Thus, also with the manufacturing method of Example 3, a battery modulein which each of the adhesion parts 42 sufficiently fills the intervalbetween the battery retention section 50 of the holder 5 and each of thebattery cells 1 can be manufactured easily.

In the adhesion layer-forming step of the manufacturing method ofExample 3, the length L2 of the back part 46 in the axial direction isset to be larger than the length L1 of the front part 45 in the axialdirection. However, the ratio of the length L2 of the back part 46 inthe axial direction with respect to the length L1 of the front part 45in the axial direction is not particularly limited in the manufacturingmethod of the present invention. For example, depending on the adhesivestrength required for the battery module, the length L2 of the back part46 in the axial direction may be smaller than the length L1 of the frontpart 45 in the axial direction.

In Example 3, the length L2 of the back part 46 in the axial directionis set to be larger than the length L1 of the front part 45 in the axialdirection in order to increase the proportion of the adhesive in theadhesion layer 4 and increase the adhesive strength of the adhesionlayer 4. From a standpoint of the adhesive strength, the length L2 ofthe back part 46 in the axial direction is preferably larger than thelength L1 of the front part 45 in the axial direction. Morespecifically, the length L2 of the back part 46 in the axial directionis preferably at least two times, more preferably three times, largerthan the length L1 of the front part 45 in the axial direction.

The porous layer 40 used in the manufacturing method of Example 3 doesnot have to be impregnated with the adhesive. Thus, in manufacturingmethod of Example 3, a closed-cell type porous layer 40 can be used.Also in this case, the adhesive included in the back part 46 adheres tothe front part 45 at a boundary portion with respect to the back part46. As a result, in the front part 45, fine pores having an opening atthe boundary portion are impregnated with the adhesive. Thus, also inthis case, at least one portion of the front part 45 can be consideredto be impregnated with the adhesive. At the insertion step, in order tohave the back part 46 drawn by the front part 45 with high reliability,the front part 45 is preferably adhered to the back part 46 firmly atthe adhesive layer-forming step. Thus, the surface area of the frontpart 45 at a boundary portion with respect to the back part 46 ispreferably large, and the front part 45 is preferably formed of theporous layer 40 that is an open-cell type. When the front part 45 isformed from the porous layer 40 that is an open-cell type, the wholefront part 45 is in some cases impregnated with the adhesive at theinsertion step, depending on the viscosity of the adhesive, and theratio of lengths of the front part 45 and the back part 46 in the axialdirection, etc.

The battery module of Example 3 obtained by the manufacturing method ofExample 3 is roughly identical to the battery module of Example 2 exceptfor the adhesion parts 42, but is largely different from the batterymodule of Example 2 regarding the adhesive almost not existing at thefront part 45.

The battery module of the present invention is not particularly limitedin terms of its use application, and can be disposed in various devicesand equipment, etc. Specific examples thereof include assembledbatteries to be mounted on vehicles.

(Note 1)

The present invention is not limited to the embodiments described aboveand in the drawings, and can be implemented after being appropriatelymodified without departing from the gist of the invention. Furthermore,components shown in the embodiments may be extracted and freely combinedto be implemented.

(Note 2)

The method for manufacturing the battery module of the present inventioncan be expressed as described in the following.

(1) A method for manufacturing a battery module, the method including: apreparing step of preparing a battery cell 1 and a holder 5 having abattery retention section 50 with a hole; an adhesion layer-forming stepof forming an adhesion layer 4 on an outer circumferential surface 11 ofthe battery cell 1; and an insertion step of inserting the battery cell1 in the battery retention section 50 of the holder 5, wherein

in the adhesion layer-forming step, a deformable porous layer 40 isformed on the outer circumferential surface 11 of the battery cell 1 andthe porous layer 40 is impregnated with an adhesive to form an adhesionlayer including the porous layer and the adhesive.

(2) A method for manufacturing a battery module, the method including: apreparing step of preparing a battery cell 1 and a holder 5 having abattery retention section 50 with a hole; an adhesion layer-forming stepof forming an adhesion layer 4 on an outer circumferential surface 11 ofthe battery cell 1; and an insertion step of inserting the battery cell1 in the battery retention section 50 of the holder 5, wherein

at the adhesion layer-forming step,

a deformable porous layer 40 is formed in a first area I which is a partof the outer circumferential surface 11 of the battery cell 1, and

an adhesion layer including an adhesive is formed on a second area IIlocated adjacent to the first area I and on a back side thereof in aninsertion direction for the battery cell 1 to form an adhesive layerincluding the porous layer and the adhesive.

(3) The manufacturing method the battery module according to (1) or (2),wherein

at the adhesion layer-forming step,

at least at one part of an area of the outer circumferential surface 11of the battery cell 1 in the axial direction Y, the adhesion layer 4 isformed on a whole circumference of the outer circumferential surface 11of the battery cells 1.

(4) The method for manufacturing the battery module according to any oneof (1) to (3), wherein the porous layer 40 is elastically deformable.(5) The method for manufacturing of the battery module according to anyone of (2) to (4), wherein at the adhesion layer-forming step, theporous layer 40 and the adhesive layer are brought in contact with eachother.(6) The method for manufacturing the battery module according to any oneof (2) to (5), wherein at the adhesion layer-forming step, the porouslayer 40 is impregnated with a low viscosity adhesive having a lowerviscosity than that of the adhesive included in the adhesive layer.(7) A battery module including: a holder 5 having a battery retentionsection 50 with a hole; a battery cell 1 inserted in the batteryretention section 50 of the holder 5; and an adhesion part 42 interposedbetween the holder 5 and the battery cell 1, wherein

the adhesion part 42 includes a porous layer 40, and an adhesiveimpregnating at least one part of the porous layer 40.

1. A method for manufacturing a battery module, the method comprising:preparing a battery cell and a holder having a battery retention sectionwith a hole; forming an adhesion layer on an outer circumferentialsurface of the battery cell; and inserting the battery cell in thebattery retention section of the holder, wherein, at the forming of theadhesion layer, a deformable porous layer is formed on the outercircumferential surface of the battery cell and the porous layer isimpregnated with an adhesive to form an adhesion layer including theporous layer and the adhesive.
 2. A method for manufacturing a batterymodule, the method comprising: preparing a battery cell and a holderhaving a battery retention section with a hole; forming an adhesionlayer on an outer circumferential surface of the battery cell; andinserting the battery cell in the battery retention section of theholder, wherein at the forming of the adhesion layer, a deformableporous layer is formed in a first area which is a part of the outercircumferential surface of the battery cell, and an adhesive layerincluding an adhesive is formed on a second area located adjacent to thefirst area and on a back side thereof in an insertion direction for thebattery cell to form an adhesion layer including the porous layer andthe adhesive.
 3. The method for manufacturing the battery moduleaccording to claim 1, wherein at the forming of the adhesion layer, atleast at one part of an area of the outer circumferential surface of thebattery cell in an axial direction, the adhesion layer is formed on awhole circumference of the outer circumferential surface of the batterycell.
 4. The method for manufacturing the battery module according toclaim 1, wherein the porous layer is elastically deformable.
 5. Themethod for manufacturing the battery module according to claim 2,wherein at the forming of the adhesion layer, at least at one part of anarea of the outer circumferential surface of the battery cell in anaxial direction, the adhesion layer is formed on a whole circumferenceof the outer circumferential surface of the battery cell.
 6. The methodfor manufacturing the battery module according to claim 2, wherein theporous layer is elastically deformable.
 7. The method for manufacturingthe battery module according to claim 2, wherein at the forming of theadhesion layer, the porous layer and the adhesive layer are brought incontact with each other.
 8. The method for manufacturing the batterymodule according to claim 2, wherein at the forming of the adhesionlayer, the porous layer is impregnated with a low viscosity adhesivehaving a lower viscosity than that of the adhesive included in theadhesive layer.
 9. A battery module comprising: a holder having abattery retention section with a hole; a battery cell inserted in thebattery retention section of the holder; and an adhesion part interposedbetween the holder and the battery cell, wherein the adhesion partincludes a porous layer, and an adhesive impregnating at least one partof the porous layer.